COIL DEVICE

BACKGROUND OF THE INVENTION
Field of the Invention

The present invention relates to a coil device used as, for example, an inductor.

Description of the Related Art

As a coil device known as an inductor or the like, for example, a coil device described in Japanese Patent Laid-Open No. 2018-133402 (Patent Literature 1) is known. The coil device described in Patent Literature 1 includes an element body, a coil disposed inside the element body, and a terminal connected to a lead portion of the coil. The terminal includes a wire connecting portion to which the lead portion of the coil is fixed, and a locking piece that clamps the lead portion of the coil fixed to the wire connecting portion.

The coil device described above is obtained by disposing a coil and a terminal (a terminal in a state of being connected with the lead portion of the coil) inside a mold, filling the mold with a magnetic material that constitutes the element body, and performing compression molding. In the coil device described in Patent Literature 1, since the lead portion of the coil is fixed to the wire connecting portion and clamped by the locking piece, problems such as disconnection of the lead portion of the coil due to pressure during compression molding can be prevented.

However, in the coil device described in Patent Literature 1, the following problems may occur during compression molding. That is, in the coil device described in Patent Literature 1, the locking piece clamps the lead portion of the coil so as to wind around the lead portion of the coil fixed to the wire connecting portion. Therefore, a part of the locking piece (and a part of the wire connecting portion) is disposed protruding inside the lead portion of the coil (a space sandwiched between the lead portion of the coil and an outer peripheral surface of the coil), and thus it is difficult to fill a sufficient amount of the element body inside the lead portion of the coil (a space surrounded by the lead portion of the coil, the outer peripheral surface of the coil, and the locking piece) due to this protruding. Therefore, a density of the element body cannot be sufficiently ensured, and inductance characteristics of the coil device may deteriorate.

In order to avoid the above-described problem, for example, it is conceivable to increase pressure during the compression molding to forcibly push the element body into the above-described space inside the lead portion of the coil. However, such high-pressure molding may lead to problems such as deformation of the coil, which is a factor in degrading quality of the coil device.

SUMMARY OF THE INVENTION

The present invention is made in view of such circumstances, and an object thereof is to provide a coil device having good inductance characteristics and high quality.

In order to achieve the above object, a coil device according to the present invention includes:

a first terminal including a first wire connecting portion connected to a first lead portion of a coil;

a second terminal including a second wire connecting portion connected to a second lead portion of the coil; and

an element body covering the coil together with the first wire connecting portion and the second wire connecting portion, in which the first lead portion is led out in a front-rear direction of the element body, the second lead portion is led out in the front-rear direction of the element body, the first wire connecting portion is positioned outside the first lead portion along a left-right direction perpendicular to the front-rear direction of the element body, and the second wire connecting portion is positioned outside the second lead portion along the left-right direction perpendicular to the front-rear direction of the element body.

In the coil device according to the present invention, the first wire connecting portion is positioned outside the first lead portion along the left-right direction of the element body. Therefore, the first wire connecting portion does not significantly protrude inside the first lead portion (the space sandwiched between the first lead portion and the outer peripheral surface of the coil), and when the space inside the first lead portion is filled with the element body, the first wire connecting portion does not become a physical obstacle to this filling. Therefore, it is possible to fill the space inside the first lead portion with a sufficient amount of the element body without being obstructed by the first wire connecting portion (similarly, it is possible to fill the space inside the second lead portion with a sufficient amount of the element body without being obstructed by the second wire connecting portion), and the density of the element body can be sufficiently secured, and a coil device having good inductance characteristics can be obtained.

During compression molding, the space inside the first lead portion and the space inside the second lead portion can be easily filled with a sufficient amount of the element body without using high-pressure molding, and it is possible to prevent occurrence of defects such as deformation of the coil device and obtain a high-quality coil device.

Preferably, the coil is disposed inside the element body such that each of thickness directions of the first lead portion and the second lead portion substantially coincide with the left-right direction of the element body, an outer surface in the thickness direction of the first lead portion is mainly connected to an inner edge of the first wire connecting portion, and an outer surface in the thickness direction of the second lead portion is mainly connected to an inner edge of the second wire connecting portion. By using the outer surface of the first lead portion as a connecting surface with the first wire connecting portion and connecting the outer surface to the inner edge of the first wire connecting portion, it is possible to effectively prevent the first wire connecting portion from protruding into the space inside the first lead portion. Similarly, by using the outer surface of the second lead portion as a connecting surface with the second wire connecting portion and connecting the outer surface to the inner edge of the second wire connecting portion, it is possible to effectively prevent the second wire connecting portion from protruding into the space inside the second lead portion. Accordingly, formation of physical obstacles that obstruct the filling of the element body in the space inside the first lead portion and the space inside the second lead portion can be prevented, and the spaces can be easily filled with a sufficient amount of the element body.

Preferably, the first lead portion is connected to the first wire connecting portion at a first connecting portion, the second lead portion is connected to the second wire connecting portion at a second connecting portion, the first connecting portion is unevenly distributed outside the first lead portion in a thickness direction of the first lead portion, and the second connecting portion is unevenly distributed outside the second lead portion in a thickness direction of the second lead portion. With such a configuration, the first connecting portion does not protrude significantly into the space inside the first lead portion, and when the space inside the first lead portion is filled with the element body, the first connecting portion does not become a physical obstacle to this filling. Similarly, the second connecting portion does not protrude significantly into the space inside the second lead portion, and when the space inside the second lead portion is filled with the element body, the second connecting portion does not become a physical obstacle to this filling. Therefore, the space inside the first lead portion and the space inside the second lead portion can be easily filled with a sufficient amount of the element body without being obstructed by the first connecting portion and the second connecting portion.

Preferably, the first lead portion and the second lead portion are led out in substantially the same direction along the front-rear direction of the element body. With such a configuration, when connecting the first lead portion and the second lead portion to the first wire connecting portion and the second wire connecting portion, respectively, by laser welding for example, it is possible to irradiate the first lead portion and the second lead portion with laser from the same direction, and laser welding is easy.

Preferably, when the element body is viewed from the front-rear direction, at least a part of the first lead portion is positioned inside a first lead-out position on an outer peripheral surface of the coil from which the first lead portion is led out, and at least a part of the second lead portion is positioned inside a second lead-out position on the outer peripheral surface of the coil from which the second lead portion is led out, along the left-right direction of the element body. With such a configuration, an elastic force that tries to return the first lead portion to the first lead-out position acts on the first lead portion, so that the first lead portion is fixed to the first wire connecting portion in a biased state. Similarly, an elastic force that tries to return the second lead portion to the second lead-out position acts on the second lead portion, so that the second lead portion is fixed to the second wire connecting portion in a biased state. Therefore, connection between the first lead portion and the first wire connecting portion can be maintained satisfactorily, and connection between the second lead portion and the second wire connecting portion can be maintained satisfactorily.

Preferably, the first terminal further includes a first base portion disposed substantially parallel to a bottom surface of the element body, the second terminal further includes a second base portion disposed substantially parallel to the bottom surface of the element body, the first wire connecting portion extends upward from the first base portion, and the second wire connecting portion extends upward from the second base portion. With such a configuration, it is possible to appropriately adjust a height of the first wire connecting portion according to a height of the first lead-out position, and the first lead portion can be led out to the position of the first wire connecting portion and connected thereto without being bent unnecessarily. Similarly, it is possible to appropriately adjust a height of the second wire connecting portion according to a height of the second lead-out position, and the second lead portion can be led out to the position of the second wire connecting portion and connected thereto without being bent unnecessarily.

Preferably, an inner edge of the first base portion is positioned outside an inner surface of the first lead portion in a thickness direction of the first lead portion along the left-right direction of the element body, and an inner edge of the second base portion is positioned outside an inner surface of the second lead portion in a thickness direction of the second lead portion along the left-right direction of the element body. With such a configuration, the first base portion does not protrude significantly into the space inside the first lead portion, and when the space inside the first lead portion is filled with the element body, the first base portion does not become a physical obstacle to this filling. Therefore, it is possible to fill the space inside the first lead portion with a sufficient amount of the element body without being obstructed by the first base portion (similarly, it is possible to fill the space inside the second lead portion with a sufficient amount of the element body without being obstructed by the second base portion), and the density of the element body can be sufficiently secured, and a coil device having good inductance characteristics can be obtained.

Preferably, a position of an end portion of the first wire connecting portion along a winding axis direction of the coil and a position of an end portion of the second wire connecting portion along the winding axis direction of the coil are displaced from each other. With such a configuration, when the first lead-out position and the second lead-out position are displaced from each other along a winding axis of the coil, it is possible to adapt the height of the first wire connecting portion to the height of the first lead-out position, and to adapt the height of the second wire connecting portion to the height of the second lead-out position. Therefore, the first lead portion can be led out to the position of the first wire connecting portion and connected thereto without being bent unnecessarily. The second lead portion can be led out to the position of the second wire connecting portion and connected thereto without being bent unnecessarily.

Preferably, the first lead portion is positioned above the second lead portion along a winding axis direction of the coil, and a length of the first wire connecting portion along the winding axis direction of the coil is longer than a length of the second wire connecting portion along the winding axis direction of the coil. With such a configuration, it is possible to match the position of the first wire connecting portion to the height of the first lead-out position, and the first lead portion can be led out to the position of the first wire connecting portion and connected thereto without being bent unnecessarily.

Preferably, a notch portion cut along a winding axis direction of the coil is formed on an inner edge of the first wire connecting portion, and the first lead portion is fixed at a position spaced upward from a bottom of the notch portion in the winding axial direction. By forming the notch portion for fixing the first lead portion on the inner edge of the first wire connecting portion, it is possible to reduce a size of the first wire connecting portion, and it is possible to effectively prevent the first wire connecting portion from protruding into the space inside the first lead portion. By fixing the first lead portion to the notch portion, it is possible to prevent the first lead portion itself from protruding significantly toward a center of the coil, and formation of an area that is difficult to be filled with the element body can be effectively prevented in the space inside the first lead portion. By fixing the first lead portion at the position spaced upward from the bottom of the notch portion, even if the first lead-out position of the first lead portion varies along the winding axis direction of the coil, the first lead portion can be reliably fixed to the notch portion without contacting the bottom of the notch portion.

Preferably, the first lead portion is connected to the first wire connecting portion at a position spaced upward from an upper surface of the first base portion, and the second lead portion is placed on the second base portion and connected to the second wire connecting portion. With such a configuration, the first lead portion and the second lead portion can be led out to the positions of the first wire connecting portion and the second wire connecting portion and connected thereto without being bent unnecessarily. Since the second lead portion is fixed to the second base portion, it is possible to effectively prevent displacement of the second lead portion (and the entire coil) due to pressure during compression molding.

Preferably, the first base portion includes a first main branch portion and a first sub branch portion, the first main branch includes a first main protruding portion protruding forward of the element body, the first sub branch portion includes a first sub protruding portion protruding rearward of the element body, and one of the first main protruding portion and the first sub protruding portion is displaced from the other of the first main protruding portion and the first sub protruding portion along the left-right direction of the element body. With such a configuration, the first terminal can be prevented from coming off from the element body and displacement of the first base portion in the element body can be prevented particularly in the left-right direction of the element body by an anchoring effect of the first main protruding portion and the first sub protruding portion. By displacing one of the first main protruding portion and the first sub protruding portion relative to the other along the left-right direction of the element body, an area occupied by the first main protruding portion and the first sub protruding portion inside the element body can be sufficiently ensured, so that the above effect can be effectively obtained.

Preferably, an outer edge of the first main branch portion is curved forward from a side of the element body inside the element body, an outer edge of the first sub branch portion is curved rearward from a side of the element body inside the element body, and a radius of curvature of the outer edge of the first main branch is different from a radius of curvature of the outer edge of the first sub branch portion. With such a configuration, the first terminal can be prevented from coming off from the element body and displacement of the first base portion in the element body can be prevented particularly in the left-right direction of the element body by an anchoring effect of the first main branch portion and the first sub branch portion. By making the radius of curvature of the outer edge of the first main branch portion different from the radius of curvature of the outer edge of the first sub branch portion, the first main branch portion or the first sub branch portion may be provided with a sufficient size to achieve the above effect, so that the above effect can be effectively obtained.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of a coil device according to a first embodiment of the present invention;

FIG. 2 is a perspective view showing an internal configuration of the coil device shown in FIG. 1;

FIG. 3 is a perspective view of a coil shown in FIG. 2;

FIG. 4 is a perspective view of a pair of terminals shown in FIG. 2;

FIG. 5A is a side view showing a state in which a lead portion of the coil is connected to the pair of terminals shown in FIG. 4;

FIG. 5B is a perspective view showing a state of the pair of terminals and the coil shown in FIG. 5A when viewed from another angle;

FIG. 6 is a plan view showing a state of the coil device shown in FIG. 2 when viewed from a bottom surface;

FIG. 7A is a diagram showing a method for manufacturing the coil device shown in FIG. 1;

FIG. 7B is a diagram showing a step subsequent to FIG. 7A;

FIG. 7C is a diagram showing a step subsequent to FIG. 7B;

FIG. 7D is a diagram showing a step subsequent to FIG. 7C;

FIG. 7E is a diagram showing a step subsequent to FIG. 7D;

FIG. 7F is a diagram showing a step subsequent to FIG. 7E;

FIG. 8 is a perspective view of a coil device according to a second embodiment of the present invention; and

FIG. 9 is a perspective view of a pair of terminals shown in FIG. 8.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Hereinafter, the present invention will be described based on embodiments shown in the drawings.

First Embodiment

As shown in FIG. 1, an inductor 1 according to a first embodiment of the present invention is a surface-mounted inductor and has a substantially rectangular parallelepiped shape. In FIG. 1, a surface of the inductor 1 on a negative side of a Z-axis direction is a mounting surface 8a, which is disposed facing a circuit board or the like. Hereinafter, a surface of the inductor 1 that is opposite to the mounting surface 8a is referred to as a non-mounting surface 8b. In the drawing, an X-axis direction corresponds to a left-right direction of a core 8, an Y-axis direction corresponds to a front-rear direction of the core 8, and the Z-axis direction corresponds to an up-down direction of the core 8.

As shown in FIG. 2, the inductor 1 includes a coil 2, a pair of terminals 4a, 4b, and the core (element body) 8. Note that FIG. 2 shows a state in which the inductor 1 shown in FIG. 1 is inverted in the up-down direction and the left-right direction. Therefore, the mounting surface 8a of the inductor 1 is disposed on an upper side of a paper surface, and the non-mounting surface 8b of the inductor 1 is disposed on a lower side of the paper surface.

In the following description, for ease of understanding, the upper side of the paper surface (the negative side of the Z-axis direction in FIG. 2) is defined as an upper side of the inductor 1, and the lower side of the paper surface (a positive side of the Z-axis direction in FIG. 2) is defined as a lower side of the inductor 1. A front side of the paper surface (a positive side of the Y-axis direction in FIG. 2) is defined as a front side of the inductor 1, and a back side of the paper surface (a negative side of the Y-axis direction in FIG. 2) is defined as a rear side of the inductor 1. A direction away from a center of the core 8 or the coil 2 is defined as outside, and a direction toward the center of the core 8 or the coil 2 is defined as inside.

Although dimensions of the inductor 1 are not particularly limited, a width thereof in the X-axis direction is preferably 2 to 20 mm, a width thereof in the Y-axis direction is preferably 2 to 20 mm, and a width thereof in the Z-axis direction is preferably 1 to 10 mm.

The core 8 is made of a mixture containing magnetic powder and binder resin, and is formed by combining a first core 5 and a second core 6 shown in FIG. 7C. That is, the core 8 is formed by compression-molding the previously molded first core 5 and second core 6 inside a mold and integrating the first core 5 and the second core 6. Note that a boundary between the first core 5 and the second core 6 cannot be identified, and the first core 5 and the second core 6 are completely integrated together.

The core 8 (the first core 5 and/or the second core 6) is made of synthetic resin in which ferrite particles or metal magnetic particles are dispersed. However, a material constituting the core 8 is not limited thereto, and the core 8 may be constituted by a synthetic resin that does not contain these particles. Examples of the ferrite particles include Ni—Zn ferrite and Mn—Zn ferrite. The metal magnetic particles are not particularly limited, and examples thereof include Fe—Ni alloy powder, Fe—Si alloy powder, Fe—Si—Cr alloy powder, Fe—Co alloy powder, Fe—Si—Al alloy powder, and amorphous iron.

The synthetic resin contained in the core 8 is not particularly limited, and preferable examples thereof include epoxy resin, phenol resin, polyester resin, polyurethane resin, polyimide resin, and silicone resin.

As shown in FIG. 3, the coil 2 is a flatwise coil. The coil 2 is formed by, for example, a-winding a wire 3 made of a flat wire, and includes two layers along the Z-axis direction. By forming the coil 2 with a flat wire, a relatively large current can flow through the coil 2, deformation of the coil 2 is unlikely to occur, and a high-quality inductor 1 can be obtained. Note that a winding method of the wire 3 is not limited to the a winding, and may be changed as appropriate.

A winding axis direction of the coil 2 corresponds to the Z-axis direction. The wire 3 is wound such that two relatively wide surfaces among four side surfaces constituting an outer surface of the flat wire face inner and outer peripheral sides of the coil 2. Note that the wire 3 may be wound such that two relatively narrow surfaces among the four side surfaces constituting the outer surface of the flat wire face the inner and outer peripheral sides of the coil 2, so as to form the coil 2, which is an edgewise coil.

The coil 2 is an air-cored coil, and as shown in FIG. 2, the coil 2 is embedded inside the core 8. The coil 2 is disposed inside the core 8 such that a thickness direction of lead portions 3a, 3b substantially coincides with the X-axis direction (the left-right direction of the core 8).

Examples of a material constituting the wire 3 include a good conductor of metal such as copper, copper alloys, silver, and nickel, but the material is not particularly limited as long as it is a conductive material. The wire 3 is an insulated coated wire, and an insulation coating 30 is formed on a surface of the wire 3. Resin constituting the insulation coating 30 is not particularly limited, but for example, a polyamide-imide resin, a urethane resin, or the like is used. As the wire 3, a self-welding wire including a welding coating outside the insulation coating may be used. Although the resin constituting the welding coating is not particularly limited, for example, a polyamide resin, an epoxy resin, or the like is used. The insulation coating 30 is removed from the wire 3 at positions of the lead portions 3a, 3b in order to establish electrical connection with the terminals 4a, 4b.

As shown in FIG. 3, in a second layer of the coil 2, the lead portion 3a of the wire 3 is led out of the coil 2 from a first lead-out position 2c positioned on an outer peripheral surface 2e of the coil 2 and extends along the Y-axis direction linearly. In a first layer of the coil 2, the lead portion 3b of the wire 3 is led out of the coil 2 from a second lead-out position 2d positioned on the outer peripheral surface 2e of the coil 2 and extends along the Y-axis direction linearly. The lead portions 3a, 3b are led out in the same direction (Y-axis direction) without being twisted or bent. The first lead-out position 2c and the second lead-out position 2d are displaced along the Z-axis direction, and the lead portions 3a, 3b are displaced along the Z-axis direction.

In the state shown in FIG. 3, the lead portions 3a, 3b are led out along the Y-axis direction, but when connected to the wire connecting portions 42a, 42b, the lead portions 3a, 3b are inclined inwardly with respect to the Y-axis.

As shown in FIG. 4, the terminal 4a includes a base portion 41a, a wire connecting portion 42a, a connecting portion 43a, and a mounting portion 44a. The terminal 4b includes a base portion 41b, a wire connecting portion 42b, a connecting portion 43b, and a mounting portion 44b. The terminals 4a, 4b are formed by machining a conductive plate material such as metal.

As shown in FIG. 5A, the base portions 41a and 41b are positioned at substantially the same height as a bottom surface 2b of the coil 2 and are arranged substantially parallel to the bottom surface (non-mounting surface 8b) of the core 8 shown in FIG. 2. In the present embodiment, upper surfaces of the base portions 41a, 41b and the bottom surface 2b of the coil 2 are positioned substantially on the same plane. The wire connecting portions 42a, 42b are formed integrally with the base portions 41a, 41b, and the base portions 41a, 41b exert an effect of holding the wire connecting portions 42a, 42b.

As shown in FIG. 4, the base portion 41a includes a main branch portion 410a and a sub branch portion 411a, and the base portion 41b includes a main branch portion 410b and a sub branch portion 411b. The base portions 41a, 41b both have a bifurcated shape and have a common shape except for a part. Since description of the base portion 41a (the main branch portion 410a and the sub branch portion 411a) is also applicable to the base portion 41b (the main branch portion 410b and the sub branch portion 411b), only particularly necessary matters will be explained for the latter.

The wire connecting portion 42a is connected to an end portion of the main branch portion 410a (more specifically, a main protruding portion 412a, which will be described later) on the positive side of the Y-axis direction, and the main branch portion 410a holds the wire connecting portion 42a. End portions of the main branch portion 410a and the sub branch portion 411a on the negative side of the X-axis direction are both connected to a lower end portion of the connecting portion 43a. The main branch portion 410a extends further outward in the Y-axis direction than an end portion of the connecting portion 43a on the positive side of the Y-axis direction, and the sub branch portion 411a extends further outward in the Y-axis direction than an end portion of the connecting portion 43a on the negative side of the Y-axis direction.

A groove portion 45a is formed between the main branch portion 410a and the sub branch portion 411a. The groove portion 45a forms a gap between the main branch portion 410a and the sub branch portion 411a so that the base portion 41a has a bifurcated shape.

The main branch portion 410a is positioned on the positive side of the Y-axis direction of the groove portion 45a, and the sub branch portion 411a is positioned on the negative side of the Y-axis direction of the groove portion 45a. Each of the main branch portion 410a and the sub branch portion 411a is bent in a substantially L shape as a whole. That is, the main branch portion 410a extends inward in the X-axis direction from a lower end portion of the connecting portion 43a, turns to the Y-axis direction, and extends toward the positive side of the Y-axis direction. The sub branch portion 411a extends inward in the X-axis direction from the lower end portion of the connecting portion 43a, turns to the Y-axis direction, and extends toward the negative side of the Y-axis direction.

As shown in FIG. 6, inside the core 8, the main branch portion 410a and the sub branch portion 411a extend away from each other. That is, the main branch portion 410a extends so as to bend forward from a side of the core 8. The sub branch portion 411a extends so as to bend rearward from a side of the core 8. Note that the core 8 covers the coil 2 together with the wire connecting portion 42a and the base portion 41a (the main branch portion 410a and the sub branch portion 411a).

An outer edge 410a1 of the main branch portion 410a is smoothly curved forward from the side of the core 8 in line with an overall shape of the main branch portion 410a. An outer edge 411a1 of the sub branch portion 411a is smoothly curved rearward from the side of the core 8 in line with an overall shape of the sub branch portion 411a. A radius of curvature R1 of the outer edge 410a1 of the main branch portion 410a is different from a radius of curvature R2 of the outer edge 411a1 of the sub branch portion 411a. In the present embodiment, R1>R2, but R1<R2 is also possible.

By curving the outer edge 410a1 of the main branch portion 410a and the outer edge 411a1 of the sub branch portion 411a, the terminal 4a can be prevented from coming off from the core 8 and displacement of the base portion 41a in the core 8 can be prevented particularly in the left-right direction of the core 8 by an anchoring effect of the main branch portion 410a and the sub branch portion 411a. By making the radius of curvature of the outer edge 410a1 of the main branch portion 410a different from the radius of curvature of the outer edge 411a1 of the sub branch portion 411a, the main branch portion 410a and the sub branch portion 411a may be provided with a sufficient size to achieve the above effect, so that the above effect can be effectively obtained.

The main branch portion 410a includes the main protruding portion 412a that protrudes (extends) forward of the core 8. The sub branch portion 411a includes a sub protruding portion 413a that protrudes (extends) rearward of the core 8. The main branch portion 410b includes a main protruding portion 412b that protrudes forward of the core 8. The sub branch portion 411b includes a sub protruding portion 413b that protrudes rearward of the core 8.

The main protruding portion 412a is formed narrower than other portions of the main branch portion 410a, and the sub protruding portion 413a is formed narrower than other portions of the sub branch portion 411a. The sub branch portion 411a is formed narrower in the X-axis direction than the main branch portion 410a.

The main protruding portion 412a protrudes forward of the core 8 from the outer peripheral surface 2e of the coil 2 along the Y-axis direction. On the other hand, the sub protruding portion 413a protrudes rearward of the core 8 from an inner peripheral surface 2f of the coil 2 along the Y-axis direction, while does not protrude rearward of the core 8 from the outer peripheral surface 2e of the coil 2. That is, an end portion of the sub protruding portion 413a in the Y-axis direction is disposed between the inner peripheral surface 2f and the outer peripheral surface 2e of the coil 2 in the Y-axis direction.

One of the main protruding portion 412a and the sub protruding portion 413a is displaced with respect to the other along the X-axis direction of the core 8. In the present embodiment, the sub protruding portion 413a is displaced to the outside of the core 8 in the X-axis direction with respect to the main protruding portion 412a. That is, an inner edge of the sub protruding portion 413a is positioned more outside the core 8 than an inner edge of the main protruding portion 412a, and an outer edge of the sub protruding portion 413a is positioned more outside the core 8 than an outer edge of the main protruding portion 412a.

By providing the base portion 41a with the main protruding portion 412a and the sub protruding portion 413a, the terminal 4a can be prevented from coming off from the core 8 and displacement of the base portion 41a in the core 8 can be prevented particularly in the left-right direction of the core 8 by an anchoring effect of the main protruding portion 412a and the sub protruding portion 413a. By displacing one of the main protruding portion 412a and the sub protruding portion 413a relative to the other along the left-right direction of the core 8, an area occupied by the main protruding portion 412a and the sub protruding portion 413a inside the core 8 can be sufficiently ensured, so that the above effect can be effectively obtained.

As shown in FIG. 4, a main curved portion 414a is formed on an inner edge 410a2 of the main branch portion 410a, and a sub curved portion 415a is formed on an inner edge 411a2 of the sub branch portion 411a. A main curved portion 414b is formed on an inner edge 410b2 of the main branch portion 410b, and a sub curved portion 415b is formed on an inner edge 411b2 of the sub branch portion 411b.

The main curved portions 414a, 414b are mainly formed on parts of the main branch portions 410a, 410b excluding the main protruding portions 412a, 412b. The sub curved portions 415a, 415b are mainly formed on parts of the sub branch portions 411a, 411b excluding the sub protruding portions 413a, 413b.

A radius of curvature of the main curved portion 414a, a radius of curvature of the sub curved portion 415a, a radius of curvature of the main curved portion 414b, and a radius of curvature of the sub curved portion 415b are substantially equal to each other. These radiuses of curvature are approximately equal to a radius of curvature of an outer periphery (outer peripheral surface 2e) or an inner periphery (inner peripheral surface 2f) of the coil 2. Therefore, the main curved portions 414a, 414b and the sub curved portions 415a, 415b are curved along the outer peripheral surface 2e of the coil 2 at positions spaced from the outer peripheral surface 2e of the coil 2 by a predetermined distance.

As shown in FIG. 6, the inner edge 410a2 of the main branch portion 410a faces the outer peripheral surface 2e of the coil 2 with a predetermined gap D1 therebetween. The inner edge 411a2 of the sub branch portion 411a faces the outer peripheral surface 2e of the coil 2 with a predetermined gap D2 therebetween. The inner edge 410b2 of the main branch portion 410b faces the outer peripheral surface 2e of the coil 2 with a predetermined gap D3 therebetween. The inner edge 411b2 of the sub branch portion 411b faces the outer peripheral surface 2e of the coil 2 with a predetermined gap D4 therebetween. That is, none of the main branch portions 410a, 410b and the sub branch portions 411a, 411b are in contact with the coil 2, and are arranged around the outer peripheral surface 2e of the coil 2 so as to surround the outer peripheral surface 2e of the coil 2. In the present embodiment, the distance D1, the distance D2, the distance D3, and the distance D4 are substantially equal to each other on a virtual plane parallel to the bottom surface 2b of the coil 2 and the upper surfaces of the base portions 41a, 41b.

A center position of a virtual circle C defined by the main curved portion 414a, the sub curved portion 415a, the main curved portion 414b, and the sub curved portion 415b approximately coincides with a center position of the inner periphery (inner peripheral surface 2f) or the outer periphery (outer peripheral surface 2e) of the coil 2. That is, the virtual circle C and a virtual circle defined by the inner periphery (inner peripheral surface 2f) or the outer periphery (outer peripheral surface 2e) of the coil 2 are arranged concentrically.

As shown in FIG. 5A, the inner edge 410a2 of the main branch portion 410a is positioned outside an inner side surface 3a2 of the lead portion 3a in the X-axis direction. Although detailed illustration is omitted, the inner edge 411a2 (FIG. 4) of the sub branch portion 411a is similarly positioned outside the inner side surface 3a2 of the lead portion 3a in the X-axis direction. That is, the main branch portion 410a and the sub branch portion 411a do not protrude inwardly beyond the inner side surface 3a2 of the lead portion 3a.

The inner edge 410b2 of the main branch portion 410b is positioned outside an inner side surface 3b2 of the lead portion 3b in the X-axis direction. Although detailed illustration is omitted, the inner edge 411b2 (FIG. 4) of the sub branch portion 411b is similarly positioned outside the inner side surface 3b2 of the lead portion 3b in the X-axis direction. That is, the main branch portion 410b and the sub branch portion 411b do not protrude inwardly beyond the inner side surface 3b2 of the lead portion 3b.

A lead bottom portion 3b1 of the lead portion 3b led from a lower part (second lead-out position 2d) of the coil 2 is placed on an upper surface of the main branch portion 410b between the main branch portion 410a and the main branch portion 410b. As a result, the lead portion 3b is fixed to the main branch portion 410b, and during manufacture of the inductor 1 (during compression molding of the first core 5 and the second core 6 shown in FIG. 7C), positional displacement of the lead portion 3b (and the whole coil 2) due to applied pressure can be effectively prevented. Note that since the lead portion 3a of the wire 3 is led out from an upper part (first lead-out position 2c) of the coil 2, the lead portion 3a is not placed on an upper surface of the main branch portion 410a, and is disposed at a position spaced upward from the upper surface of the main branch portion 410a.

As shown in FIG. 4, only the main branch portion 410b between the main branch portion 410a and the main branch portion 410b is formed with a recess 416b. The recess 416b is formed on the inner edge 410b2 of the main branch portion 410b, and is positioned at a different position from the main curved portion 414b (forward than the main curved portion 414b). The recess 416b is provided to adjust (narrow) a width of the main protruding portion 412b and further of the wire connecting portion 42b in the X-axis direction.

The wire connecting portions 42a, 42b have a flat plate shape substantially parallel to an XZ plane, and are arranged substantially orthogonal to the lead portions 3a, 3b (see FIG. 5B). As shown in FIG. 2, the wire connecting portions 42a, 42b are arranged inside the core 8. The lead portions 3a, 3b of the wire 3 are connected to the wire connecting portions 42a, 42b. More specifically, the lead portion 3a is connected to the wire connecting portion 42a at a position spaced upward from the upper surface of the base portion 41a. The lead portion 3b is connected to the wire connecting portion 42b while being placed on the base portion 41b. In the present embodiment, since the lead portions 3a and 3b are led out in substantially the same direction (positive side of the Y-axis direction), the wire connecting portions 42a, 42b are arranged on the positive side of the Y-axis direction of the coil 2 from which the lead portions 3a, 3b are led out.

As shown in FIG. 4, the wire connecting portions 42a, 42b extend along the Z-axis direction and rise upward from the end portions on the positive side of the Y-axis direction of the main branch portions 410a, 410b. The wire connecting portions 42a, 42b are arranged substantially perpendicular to the main branch portions 410a, 410b. Rising positions of the wire connecting portions 42a, 42b are positioned forward of positions of the end portions of the connecting portions 43a, 43b on the positive side of the Y-axis direction. As shown in FIG. 2, the end portions of the base portions 41a, 41b on the positive side of the Y-axis direction are arranged outside the end portion of the coil 2 on the positive side of the Y-axis direction in the Y-axis direction, and therefore, the rising positions of the wire connecting portions 42a, 42b are positioned outside the end portion of the coil 2 on the positive side of the Y-axis direction in the Y-axis direction.

As shown in FIG. 5A, a length of the wire connecting portion 42a in the Z-axis direction is longer than a length of the wire connecting portion 42b in the Z-axis direction. The length of the wire connecting portion 42a in the Z-axis direction is longer than a length of the wire 3 in the Z-axis direction, and an upper end portion of the wire connecting portion 42a is disposed at a position corresponding to the second layer of the coil 2 (first lead-out position 2c). Therefore, when the lead portion 3a is led out from the first lead-out position 2c, the lead portion 3a can be led out to the position of the wire connecting portion 42a and connected thereto without being bent unnecessarily.

The length of the wire connecting portion 42b in the Z-axis direction is smaller than the length of the wire 3 in the Z-axis direction, and the upper end portion of the wire connecting portion 42b is disposed at a position corresponding to the first layer of the coil 2 (second lead-out position 2d). Therefore, the position of the upper end portion of the wire connecting portion 42a and the position of the upper end portion of the wire connecting portion 42b are displaced from each other along the Z-axis direction.

In this way, since the positions (heights) of the wire connecting portions 42a, 42b are adjusted to match positions (heights) of the lead-out positions 2c, 2d, the lead portions 3a, 3b can be led out to the positions of the wire connecting portions 42a, 42b and connected thereto without being bent unnecessarily.

As shown in FIG. 6, a position of a center O of the coil 2 is displaced along the Y-axis direction from a center of the core 8 to a side opposite to the wire connecting portions 42a, 42b (to a rear side of the core 8). By adopting such a configuration, it is possible to ensure a sufficient volume of the core 8 in front of the core 8. Therefore, the wire connecting portions 42a, 42b and the lead portions 3a, 3b connected thereto can be covered with a sufficient amount of the core 8 to protect the wire connecting portions 42a, 42b and the lead portions 3a, 3b. Since a sufficient space is formed in front of the core 8 for arranging the wire connecting portions 42a, 42b, there is no need to expand the core 8 forward to ensure the space, and the inductor 1 can be miniaturized.

It is possible to dispose the outer peripheral surface 2e of the coil 2 at a position sufficiently spaced from a side surface of the core 8 on the positive side of the Y-axis direction, ensure a sufficient thickness of the core 8 between the outer peripheral surface 2e of the coil 2 and the side surface of the core 8 on the positive side of the Y-axis direction, and prevent cracks from occurring on the side surface of the core 8 on the positive side of the Y-axis direction.

As shown in FIG. 5A, when the core 8 is viewed from a front side, at least a part of the lead portion 3a is positioned inside in the X-axis direction of the first lead-out position 2c on the outer peripheral surface 2e of the coil 2 where the lead portion 3a is led out. At least a part of the lead portion 3b is positioned inside in the X-axis direction of the second lead-out position 2d on the outer peripheral surface 2e of the coil 2 from which the lead portion 3b is led out. By adopting such a configuration, an elastic force that tries to return the lead portion 3a to the first lead-out position 2c (outside the X-axis direction) acts on the lead portion 3a, so that the lead portion 3a is fixed to the wire connecting portion 42a in a biased state. Similarly, an elastic force that tries to return the lead portion 3b to the second lead-out position 2d (outside the X-axis direction) acts on the lead portion 3b, so that the lead portion 3b is fixed to the wire connecting portion 42b in a biased state. Therefore, the connection between the lead portion 3a and the wire connecting portion 42a can be maintained satisfactorily, and the connection between the lead portion 3b and the wire connecting portion 42b can be maintained satisfactorily.

A notch portion 420a is formed along the Z-axis direction in an inner edge of the wire connecting portion 42a between the wire connecting portion 42a and the wire connecting portion 42b. The notch portion 420a is cut downward at a predetermined depth from an upper end of the wire connecting portion 42a. The lead portion 3a of the wire 3 can be fixed to the notch portion 420a.

A length of the notch portion 420a in the Z-axis direction is substantially the same as the length of the wire 3 in the Z-axis direction. As shown in FIG. 5A, the lead bottom portion 3a1 of the lead portion 3a is fixed at a position spaced upward from a notch bottom portion 421a and does not contact the notch bottom portion 421a. Therefore, when the lead portion 3a is fixed to the notch portion 420a, the upper end portion of the lead portion 3a protrudes above the upper end of the wire connecting portion 42a, and the lead portion 3a is entirely accommodated inside the notch portion 420a.

In this way, by fixing the lead portion 3a at a position spaced upward from the notch bottom portion 421a, even if the first lead-out position 2c of the lead portion 3a changes along the Z-axis direction, the lead portion 3a does not come into contact with the notch bottom portion 421a, and the lead portion 3a can be reliably fixed to the notch portion 420a. When connecting the lead portion 3a to the wire connecting portion 42a, the lead portion 3a can be fixed to the notch portion 420a in a state of being straightly led out without being bent.

Note that an upper end portion of the lead portion 3b also protrudes above the upper end of the wire connecting portion 42b, similarly to the upper end portion of the lead portion 3a. This is because the length of the wire connecting portion 42b in the Z-axis direction is smaller than the length of the wire 3 in the Z-axis direction due to the miniaturization of the wire connecting portion 42b.

An outer side surface 3a3 (more specifically, a part or most of the outer side surface 3a3) of the lead portion 3a is connected to the inner edge of the wire connecting portion 42a, and an outer side surface 3b3 (more specifically, a part or most of the outer side surface 3a3) of the lead portion 3b is connected to an inner edge of the wire connecting portion 42b. The inner side surface 3a2 of the lead portion 3a is not fixed to the wire connecting portion 42a, and the inner side surface 3b2 of the lead portion 3b is not fixed to the wire connecting portion 42b.

With respect to the X-axis direction, a position of the outer side surface 3a3 of the lead portion 3a is positioned more inside than a position of the outer peripheral surface 2e of the coil 2 at the first lead-out position 2c. Therefore, with respect to the X-axis direction, the inner edge of the wire connecting portion 42a is positioned between the outer side surface 3a3 of the lead portion 3a and the outer peripheral surface 2e at the first lead-out position 2c. With respect to the X-axis direction, the position of the outer side surface 3b3 of the lead portion 3b is positioned more inside than the position of the outer peripheral surface 2e of the coil 2 at the second lead-out position 2d. Therefore, the inner edge of the wire connecting portion 42b is positioned between the outer side surface 3b3 of the lead portion 3b and the outer peripheral surface 2e at the second lead-out position 2d with respect to the X-axis direction.

In the present embodiment, the wire connecting portion 42a is positioned biased outward of the lead portion 3a that is led out forward of the core 8 in the X-axis direction. Similarly, the wire connecting portion 42b is positioned biased outward of the lead portion 3b that is led out forward of the core 8 in the X-axis direction. More specifically, the inner edge of the wire connecting portion 42a is positioned outside the inner side surface 3a2 of the lead portion 3a in the X-axis direction. The inner edge of the wire connecting portion 42a is positioned outside the outer side surface 3a3 of the lead portion 3a in the X-axis direction at the position of the notch portion 420a. The inner edge of the wire connecting portion 42b is positioned outside the inner side surface 3b2 and the outer side surface 3b3 of the lead portion 3b in the X-axis direction. That is, the wire connecting portions 42a, 42b do not protrude inward in the X-axis direction beyond the inner side surfaces 3a2, 3b2 of the lead portions 3a, 3b, and the entire wire connecting portions 42a, 42b are arranged outside the inner side surfaces 3a2, 3b2 in the X-axis direction.

As shown in FIG. 2, the lead portions 3a, 3b are connected to wire connecting portions 42a, 42b via a melted portion 9. The melted portion 9 is constituted by a weld bead formed when the terminals 4a, 4b (the wire connecting portions 42a, 42b) are irradiated with a laser. Here, the melted portion 9 may be a connection member made of solder, a conductive adhesive, or the like. In the wire connecting portion 42a, the melted portion 9 is unevenly distributed outside the inner side surface 3a2 of the lead portion 3a in the X-axis direction. In the wire connecting portion 42b, the melted portion 9 is unevenly distributed outside the inner side surface 3b2 of the lead portion 3b in the X-axis direction. That is, the melted portion 9 does not substantially protrude (is not formed) inside the inner side surfaces 3a2, 3b2 of the lead portions 3a, 3b in the X-axis direction, and the entire melted portion 9 is substantially disposed outside the inner side surfaces 3a2, 3b2 in the X-axis direction.

As shown in FIG. 4, the connecting portions 43a, 43b include surfaces substantially parallel to a YZ plane and extend upward from the base portions 41a, 41b. As shown in FIG. 2, the connecting portions 43a, 43b are exposed on side surfaces of the core 8 in the X-axis direction at a position spaced upward from the non-mounting surface 8b of the core 8, and extend to the position of the mounting surface 8a of the core 8 along the side surface. Although not shown in detail, part of the groove portions 45a, 45b (FIG. 1) extends to the lower end portions of the connecting portions 43a, 43b, and the groove portions 45a, 45b are exposed on the side surfaces of the core 8 in the X-axis direction.

As shown in FIG. 4, the mounting portions 44a, 44b are connected to end portions of the connecting portions 43a, 43b in the Z-axis direction and extend inward in the X-axis direction. The mounting portions 44a, 44b include surfaces parallel to an XY plane and are formed along the mounting surface 8a of the core 8 shown in FIG. 2. The mounting portions 44a, 44b are exposed to the outside of the core 8 on the mounting surface 8a, and are connected to a circuit board or the like (not shown) when the inductor 1 is mounted.

The mounting portions 44a, 44b are connected to a circuit board or the like via a connection member such as solder or a conductive adhesive. In this case, solder fillets can be formed in the connecting portions 43a, 43b, so that a mounting strength of the inductor 1 on the circuit board or the like can be increased.

Next, a method for manufacturing the inductor 1 will be described with reference to FIGS. 7A to 7F and the like. In the method of the present embodiment, first, a conductive plate such as a metal plate (for example, a Sn-plated metal plate) is punched into a shape as shown in FIG. 7A or 7C. As shown in the same drawing, the terminals 4a, 4b connected to a frame 7 via the connecting portions 43a, 43b are formed on the conductive plate after punching. In the frame 7, the terminals 4a and 4b are arranged with a predetermined interval therebetween along the X-axis direction.

Next, as shown in FIG. 7A, the coil 2 is disposed between the terminal 4a and the terminal 4b. In this case, the coil 2 is disposed at a position spaced from the terminals 4a, 4b by a predetermined distance (distances D1 to D4 shown in FIG. 6) such that a gap is formed between the main branch portions 410a, 410b (curved portions 414a, 415a) and sub branch portions 411a, 411b (curved portions 414b, 415b) of the terminals 4a, 4b and the outer peripheral surface 2e of the coil 2. It is preferable to fix the bottom surface 2b of the coil 2 on a pedestal (a pedestal having the same thickness as the terminals 4a, 4b) so that the bottom surface 2b of the coil 2 and the upper surfaces of the main branch portions 410a, 410b and the sub branch portions 411a, 411b are arranged substantially on the same plane. In order to prevent the coil 2 from being displaced, it is preferable to fix the inner peripheral surface 2f of the coil 2 with a positioning pin or the like.

When disposing the coil 2, the outer surface 3a3 of the lead portion 3a of the wire 3 is fixed to the inner edge (notch portion 420a) of the wire connecting portion 42a, and the wire connecting portion 42a is arranged outside the outer side surface 3a3 in the X-axis direction. The outer side surface 3b3 of the lead portion 3b of the wire 3 is fixed to the inner edge of the wire connecting portion 42b, and the wire connecting portion 42b is disposed outside the outer side surface 3b3 in the X-axis direction. The lead portion 3b of the wire 3 is placed on the main branch portion 410b so that the lead bottom portion 3b1 contacts the upper surface of the main branch portion 410b.

Next, as shown in FIG. 7B, the wire connecting portions 42a, 42b are irradiated with laser to form the melted portion 9 on the wire connecting portions 42a, 42b. As a result, the lead portions 3a, 3b are connected to the wire connecting portions 42a, 42b via the melted portion 9 (see FIG. 2). In the present embodiment, since the lead portions 3a, 3b are led out to substantially the same direction along the Y-axis direction, laser irradiation can be performed on the lead portions 3a, 3b from the same direction, thereby facilitating laser welding. Note that the laser irradiation is preferably performed so that the melted portion 9 does not protrude inward in the X-axis direction to the inner side surfaces 3a2, 3b2 of the lead portions 3a, 3b.

Next, the coil 2 in which the terminals 4a, 4b are fixed to each end portion respectively is disposed inside the mold, and the coil 2 is combined with the first core 5 and the second core 6 as shown in FIG. 7C to constitute a temporary assembly shown in FIG. 7D. More specifically, the coil 2 and the base portions 41a, 41b of the terminals 4a, 4b are placed on an upper surface of the first core 5. The connecting portions 43a, 43b of the terminals 4a, 4b are exposed from the first core 5 and the second core 6, respectively. Pre-molded cores (temporary molded cores) are used as the first core 5 and the second core 6. As a material constituting the first core 5 and the second core 6, a fluid material is used, and a composite magnetic material with a thermoplastic resin or a thermosetting resin as a binder is used.

The first core 5 and the second core 6 of the temporary assembly shown in FIG. 7D are compression-molded using mold jigs (upper and lower punches and the like), and by integrating the first core 5 and the second core 6, the core 8 (FIG. 7E) is formed. In this case, by applying heat, the first core 5 and the second core 6 can be easily integrated.

Next, as shown in FIG. 7E, the frame 7 shown in FIG. 7D is cut and removed with a cutting tool so that only the connecting portions 43a, 43b remain. Then, the connecting portions 43a, 43b are fixed to side recesses 80 formed in the core 8. More specifically, as shown in FIG. 7F, the connecting portions 43a, 43b of the terminals 4a, 4b are bent substantially vertically from the state shown in FIG. 7E, and the connecting portions 43a, 43b are fixed to the side recesses 80 respectively from sides of the core 8 in the X-axis direction. In this state, the end portions of the connecting portions 43a, 43b are bent substantially vertically and fixed to end portions of the side recesses 80, respectively, which extend to the mounting surface 8a of the core 8. As a result, the mounting portions 44a, 44b of the terminals 4a, 4b are formed on the mounting surface 8a of the core 8. As described above, the inductor 1 in the present embodiment can be obtained.

As shown in FIG. 5A, in the inductor 1 of the present embodiment, the wire connecting portions 42a, 42b are positioned outside the lead portions 3a, 3b along the X-axis direction. Therefore, the wire connecting portions 42a, 42b do not significantly protrude inside the lead portions 3a, 3b (the space 10 sandwiched between the lead portion 3a and the outer peripheral surface 2e of the coil 2/the space 10 sandwiched between the lead portion 3b and the outer peripheral surface 2e of the coil 2 shown in FIG. 5A), and when the space 10 inside the lead portions 3a, 3b is filled with the core 8, the wire connecting portion 42a, 42b do not become physical obstacles to this filling. Therefore, it is possible to fill the space 10 inside the lead portions 3a, 3b with a sufficient amount of the core 8 without being obstructed by the wire connecting portions 42a, 42b, and the density of the core 8 can be sufficiently secured, and the inductor 1 having good inductance characteristics can be obtained.

During compression molding, the space 10 inside the lead portions 3a, 3b can be easily filled with a sufficient amount of the core 8 without using high-pressure molding, and it is possible to prevent occurrence of defects such as deformation of the coil 2 and obtain a high-quality inductor 1.

By using the outer surfaces 3a3, 3b3 of the lead portions 3a, 3b as connecting surfaces with the wire connecting portions 42a, 42b and connecting the outer surfaces 3a3, 3b3 to the inner edges of the wire connecting portions 42a, 42b, it is possible to effectively prevent the wire connecting portions 42a, 42b from protruding into the space 10 inside the lead portions 3a, 3b. Accordingly, formation of physical obstacles that obstruct the filling of the core 8 in the space 10 inside the lead portions 3a, 3b can be prevented, and the space can be easily filled with a sufficient amount of the core 8.

As shown in FIG. 2, the melted portion 9 is unevenly distributed outside the lead portions 3a, 3b in the X-axis direction, so that the melted portion 9 does not significantly protrude into the space 10 inside the lead portions 3a, 3b, and when the space 10 inside the lead portions 3a, 3b is filled with the core 8, the melted portion 9 does not become a physical obstacle to this filling. Therefore, the space 10 inside the lead portions 3a, 3b can be easily filled with a sufficient amount of the core 8 without being obstructed by the melted portion 9.

In addition, as shown in FIG. 6, the inner edges 410a2, 411a2 of the base portion 41a (the main branch portion 410a and the sub branch portion 411a) are positioned outside the inner surface 3a2 of the lead portion 3a in the X-axis direction. The inner edges 410b2, 411b2 of the base portion 41b (the main branch portion 410b and the sub branch portion 411b) are positioned outside the inner surface 3b2 of the lead portion 3b in the X-axis direction. Therefore, a part of the base portion 41a does not protrude significantly into the space 10 inside the lead portions 3a, 3b, and when the space 10 inside the lead portions 3a, 3b is filled with the core 8, the base portions 41a, 41b do not become physical obstacles to this filling. Therefore, it is possible to fill the space 10 inside the lead portions 3a, 3b with a sufficient amount of the core 8 without being obstructed by the base portions 41a, 41b, and the density of the core 8 can be sufficiently secured, and the inductor 1 having good inductance characteristics can be obtained.

As shown in FIG. 5A, the notch portion 420a is formed on the inner edge of the wire connecting portion 42a, and the lead portion 3a is fixed at a position spaced upward from the notch bottom portion 421a of the notch portion 420a. By forming the notch portion 420a for fixing the lead portion 3a on the inner edge of the wire connecting portion 42a, it is possible to reduce the size of the wire connecting portion 42a, and it is possible to effectively prevent the wire connecting portion 42a from protruding into the space 10 inside the lead portion 3a. By fixing the lead portion 3a to the notch portion 420a, it is possible to prevent the lead portion 3a itself from protruding significantly toward a center of the coil 2, and formation of an area that is difficult to be filled with the core 8 can be effectively prevented in the space 10 inside the lead portion 3a.

Second Embodiment

An inductor 1A according to a second embodiment of the present invention shown in FIG. 8 has the same configuration as the inductor 1 according to the first embodiment except for the following points. In FIG. 8, members that are the same as those in the inductor 1 according to the first embodiment are denoted by the same reference numerals, and detailed description thereof will be omitted.

As shown in FIG. 8, the inductor 1A includes terminals 4aA, 4bA, which differ from the terminals 4a, 4b in the first embodiment in that the terminals 4aA, 4bA include base portions 41aA, 41bA. As shown in FIG. 9, the base portions 41aA, 41bA do not have a bifurcated shape, unlike the base portions 41a, 41b (FIG. 4) in the first embodiment, and have a substantially rectangular shape.

As shown in FIG. 8, in the present embodiment, each end portion of the bottom surface 2b of the coil 2 in the X-axis direction are placed on upper surfaces of the base portions 41aA, 41bA, and the coil 2 is supported by the base portions 41aA, 41bA. As described above, the coil 2 is disposed inside the core 8 so that a center thereof is displaced rearward from the center of the core 8. Therefore, as shown in FIG. 9, the base portions 41aA, 41bA protrude rearward (outward) in the Y-axis direction more than the connecting portions 43a, 43b in order to support the coil 2 that is displaced rearward thereof.

The present embodiment also has the same effect as the first embodiment. In the present embodiment, when the inductor 1A is manufactured, the coil 2 can be disposed inside the mold together with the terminals 4aA, 4bA with the bottom surface of the coil 2 placed on the base portions 41aA, 41bA. By mounting the bottom surface of the coil 2 on the base portions 41aA, 41bA in this way, the bottom surface of the coil 2 is supported by the base portions 41aA, 41bA. Therefore, the coil 2 is less likely to be displaced in the Z-axis direction, and the position of the bottom surface of the coil 2 is fixed to the position of the upper surfaces of the base portions 41aA, 41bA even if pressure is applied to the coil 2 during compression molding. Therefore, it is possible to set the position of the coil 2 at a predetermined position inside the core 8, thereby preventing variations in inductance characteristics and the like for each product due to variations in the position of the coil 2, and an inductor 1A with a high reliability can be obtained.

Note that the present invention is not limited to the above embodiments, and various modifications can be made within the scope of the present invention.

In each of the above-described embodiments, application examples of the present invention to inductors have been shown, but the present invention may be applied to coil devices other than inductors.

In each of the above embodiments, the wire 3 is made of a flat wire, but may be made of a wire other than a flat wire such as a round wire or a square wire.

In each of the above-described embodiments, the wire 3 is wound in a circular spiral shape, but it may be in an elliptical spiral shape, an angular spiral shape, or the like.

In each of the above embodiments, the core 8 is constituted by two cores, the first core 5 and the second core 6, but the core 8 of the inductor 1 may be constituted by only one core. In this case, the core 8 may be formed inside the mold by compaction molding, injection molding, or the like.

REFERENCE SIGNS LIST

1, 1A inductor (coil device)

2 coil

2
a upper surface

2
b bottom surface

2
c first lead-out position

2
d second lead-out position

2
e outer peripheral surface

2
f inner peripheral surface

3 wire

3
a, 3b lead portion

3
a
1, 3b1 lead bottom portion

3
a
2, 3b2 inner side surface

3
a
3, 3b3 outer side surface

30 insulation coating

4
a, 4b, 4aA, 4bA terminal

41
a, 41b, 41aA, 41bA base portion

410
a, 410b main branch portion

411
a, 411b sub branch portion

412
a, 412b main protruding portion

413
a, 413b sub protruding portion

414
a, 414b main curved portion

415
a, 415b sub curved portion

416
b recess

42
a, 42b wire connecting portion

420
a notch portion

421
a notch bottom portion

43
a, 43b connecting portion

44
a, 44b mounting portion

45
a, 45b groove portion

5 first core

6 second core

7 frame

8 core

8
a mounting surface

8
b non-mounting surface

80 side recess

9 melted portion

COIL DEVICE

Information

Publication Number

Date Filed

Date Published

Inventors

Original Assignees

CPC

International Classifications

Abstract

Description

Claims

Priority Claims (1)